KR101976793B1 - Semiconductor lighting device - Google Patents

Abstract

The present invention provides a semiconductor lighting device capable of facilitating high output by an effective heat dissipation structure. The semiconductor lighting device comprises: a main plate; a plurality of light emitting elements arranged on one surface of the main plate; a cooling plate fixed on the other surface of the main plate; a plurality of cooling fins formed on one surface of the cooling plate and inducing an air flowing path formed along the surface of the cooling plate to a spiral typed path; and a blowing fan supplying cooling wind to one end of the plurality of cooling fins. The blowing fan and the cooling plate have a protection cap or a protection cover which covers a second surface and provides an air inlet directed toward the cooling wind and an air outlet through which the cooling fin passes.

Description

Semiconductor lighting device

The present invention relates to a semiconductor lighting apparatus, and more particularly, to an LED lighting apparatus having an effective heat dissipation structure.

BACKGROUND ART Light-emitting semiconductors, for example LEDs, are highly efficient light-emitting devices and are used in a variety of lighting devices by greatly advancing high output.

These LED lighting devices replace old incandescent lamps and fluorescent lamps and have been widely used as illumination devices for public facilities.

LEDs have an advantage of high efficiency, and since they are made of semiconductor elements, heat dissipation is widely used.

In the case of low-output LEDs, the heat dissipation of the LEDs can be performed by a simple heat sink, but a forced cooling system in which a blower fan is added to the heat sink is inevitable.

In the case of a high output LED lighting device, a heat shielding structure of a considerable size is applied for reliable heat dissipation or cooling. Such a heat dissipating structure increases the size of the entire LED lighting device and thus leads to an increase in cost.

SUMMARY OF THE INVENTION The present invention provides a semiconductor lighting device which is easy to achieve high output by an efficient heat dissipation structure.

The present invention provides a semiconductor lighting device capable of reducing the size of a heat dissipation structure with high output.

A semiconductor lighting device according to the present invention comprises:
A main plate having a first surface and a second surface opposite to the first surface; A plurality of light emitting elements arranged on a first surface of the main plate; An awning formed on an upper surface of the main plate; A rotatable support bracket for installation on other structures; A cooling plate having a first surface fixed to a second surface of the main plate and a second surface opposite to the first surface, the air inlet being provided at a portion corresponding to the central portion, and a fixing pillar being formed at both sides of the rear surface or the rear surface; The cooling plate being vertically protruded from the plane of the second surface of the cooling plate and being arranged radially outwardly and radially curved about a central portion of the cooling plate, A plurality of cooling fins formed in a widened curved cross-sectional shape to guide the air flow path formed along the surface of the cooling plate into a spiral or spiral path; Wherein the cooling plate has a plurality of cooling fins and a plurality of cooling fins, the plurality of cooling fins having a common plane on which an upper end portion of the plurality of cooling fins is located is brought into contact with an upper end of the cooling fin to form an air flow path in a direction parallel to the plane of the cooling plate A guide plate having an air inlet hole corresponding thereto; A cone-shaped air guide formed to guide the vertically incident air around the bottom of the air inlet facing the air inlet; A blowing fan for supplying air from the outside to the air inflow portion through an air inflow hole of the guide plate and supplying cooling air to one end of the cooling fin; And an auxiliary cover covering the rear portion of the main cover, wherein a slit-shaped air inlet is provided radially between the main cover and the auxiliary cover, The main cover is rotatably supported on the support bracket by the fixing post of the cooling plate and the fastening means provided on the outside of the main cover. Respectively.

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According to an exemplary embodiment, the guide plate may be formed in the protective cover.

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According to the present invention, the heat emitted from the light emitting element can be effectively released to protect the light emitting element from thermal shock. Particularly, in the present invention, the cooling wind is advanced in the plane direction of the cooling plate, the contact time between the cooling wind and the cooling fins in contact with the cooling wind is prolonged, and the flow of the flowing air through the spiral or spiral- The distribution can be uniformly guided and the cooling efficiency can be greatly increased.

1 and 2 are schematic perspective views showing front and rear views of an LED lighting apparatus according to the present invention.
3 is a schematic side view of an LED lighting apparatus according to the present invention.
4 shows the inside of the protective cover covering the main cover in the LED lighting device according to the present invention
5 shows a rear view of a cooling device in which a protective cover is removed, in the LED lighting device according to the present invention.
6 is an exploded perspective view showing a coupling relationship between a cooling plate and a main plate mounted on a front surface thereof in the LED lighting apparatus according to the present invention.
7 shows a specific arrangement of the cooling fins of the cooling plate according to the present invention.
8 is a side view of a cooling plate showing the side of a curved cooling fin in the LED lighting apparatus according to the present invention.
Fig. 9 shows a spiral air flow path occurring between the cooling fins in the LED lighting device according to the present invention.

Hereinafter, preferred embodiments of the LED lighting apparatus according to the present invention will be described with reference to the accompanying drawings.

The present invention proposes a structure that can efficiently protect the semiconductor light emitting device by effectively dissipating heat from the light emitting device in an illumination device employing a semiconductor light emitting device such as an LED. Such a structure includes a structure for effectively performing heat cutting into cooling wind through cooling fins. The structure for efficient heat transfer maximizes the heat dissipation through the cooling fins by extending the contact time between the cooling wind and the cooling fins and inducing a uniform absorption heat distribution of the cooling wind.

1 and 2 are schematic perspective views showing front and rear views of an LED lighting apparatus according to the present invention.

Referring to FIGS. 1 and 2, a disc-shaped main plate 11 in which a plurality of LED elements 12 are disposed on one surface or a front surface of the main body of the LED lighting apparatus 100, (13) and a canopy (14). A rotatable support bracket 15 is installed on the body of the LED lighting device 100 for installing the illumination device 100 on other structures. A cooling device 20 including a cooling plate 21 is provided on the rear side of the disk-shaped main plate 11. The cooling device 20 is covered by a protective cap or a protective cover 30 and is protected from the outside have.

2, the support bracket 15 is fixed to a cooling plate 21, which is an element of the cooling device 20, and is fixed to both sides of the back surface or back surface of the cooling plate 21, 21a are formed. According to another embodiment, the fixing post piece 21a for fixing the supporting bracket 15 may be formed on another element.

The protective cover 30 includes a main cover 31 which forms an air inflow and outflow path in the cooling plate 21 in direct contact with the two elements, that is, the cooling plate 21, And an auxiliary cover (32) covering the rear side portion.

Fig. 3 is a schematic side view of the LED lighting apparatus 100. Fig. 3 shows the air inflow and outflow paths of the protective cover 30. Fig.

An air outlet 34 is provided at the edge of the main cover 31 facing the cooling plate 21 in the protective cover 30 and a narrow space slit 35 is provided between the main cover 31 and the auxiliary cover 32. [ Type air inlet 33 is provided. The auxiliary cover 32 covers an air inlet chamber (not shown) formed inside the main cover 31 and is spaced apart from the main cover 31 to form the air inlet 33. The air outlet 34 is formed by a rectangular or square groove formed uniformly at the edge of the main cover 31.

4 shows the inside of the protective cover 30 in a state where the auxiliary cover 32 covering the main cover 31 is removed.

4, the main cover 31 is provided with the above-described air inflow chamber 35. A blowing fan 40 is installed at the center of the lower floor 34 and a blowing fan 40 is installed An air inlet hole 36a is formed at the center of the bottom surface 34. [ Below the air inlet hole 36a, a conical air guide 24 formed at the center of the rear surface of the main plate 11 and a radial cooling fin 23 radially formed around the air guide 24 are positioned.

An air outlet 34 is provided between the edge of the cooling plate 21 and the edge of the main cover 31 to discharge the air introduced into the air inlet hole 36a. The air outlet 34 is formed by a cutout portion or a missing portion of a square formed at regular intervals along the edge portion of the main cover 31.

5 shows the rear surface of the cooling device 20 from which the protective cover 30 is removed.

A conical air guide 24 having an air guide surface inclined around the center of the cooling plate 21 of the cooling device 20 is disposed and a plurality of cooling fins 23 are radially formed around the air guide 24 at a predetermined interval Respectively.

The upper ends of the cooling fins 23 in the direction perpendicular to the plane of the cooling plate 21 are brought into contact with the back surface of the bottom surface 36 of the main cover 31 described above. Thus, the bottom surface 36 corresponds to an air guide plate that defines a respective air flow path between the cooling fins 23. In the figure, the triangular arrows indicate the flow direction of the air.

6 is an exploded perspective view showing a coupling relationship between the cooling plate 21 and the main plate 11 mounted on the front surface thereof.

Referring to FIG. 6, a main plate 11 on which a plurality of LEDs 12 are mounted is provided on the upper surface of a cooling plate 21 having cooling fins 23 formed on its bottom surface. A skirt 21b having a predetermined height is formed on the upper surface of the cooling plate 21 so that the edge of the main plate 11 is protected by the skirt 21b.

Fig. 7 shows a specific arrangement of the cooling fins 23 of the cooling plate 21 according to the present invention.

7, a frusto-conical air guide 24 is protruded at a predetermined height at a central portion of the cooling plate 21, and the support bracket 14 (see Figs. 1-3) And a fixed post piece 21a to be coupled therewith is formed.

A cooling fin 23 is radially disposed and extended around the cone-shaped air guide 24 as a center. The cooling fins 23 are in the form of a wall perpendicular to one surface of the cooling plate 21. The cooling fins 23 are curved in the plane direction (first direction) of the cooling plate 21 and curved in the direction perpendicular to the plane of the cooling plate 21 (second direction).

8 is a side view of the cooling plate 21 showing the sides of the cooling fins 23 curved in two directions as described above.

Referring to Fig. 8, cooling fins 23 are vertically formed in the normal direction with respect to the plane of the cooling plate 21. As shown in Fig. Here, the cooling fin 23 extends in the second direction (normal direction), but is also inclined to the cooling plate 21 in the planar direction (first). The cooling fins 23 curved in the normal direction induce the rotation of the air flowing between them, so that the cooling wind passes through the cooling fins 23 to show a helical traveling path, that is, a whirlwind air flow F . This spiral or whirlwind air flow extends the air flow distance between the cooling fins, thereby extending the contact time of the cooling wind to the cooling fins 23 and inducing even contact throughout the arena.

9 shows a spiral (whirlwind) air flow path by the cooling wind between the cooling fins 23 in a symbolic manner. 9, the curved wall surface of the curved cooling fin 23 causes the cooling wind to rotate, so that the cooling wind flows in the first direction, that is, the cooling plate 21, Along the main progress path which is parallel to the plane of FIG.

As a result, the cooling wind is brought into contact with the cooling fin 21 for a very long time, and the heat distribution of the cooling wind is uniformed by the spiral movement, thereby inducing effective heat exchange and the cooling efficiency of the main plate 11 by the cooling plate 21 Increase.

The lighting apparatus of the present invention as described above has a cooling structure with a very high cooling efficiency, and thus effectively cools the LED element emitting high heat, thereby greatly extending the entire life of the lighting apparatus.

While this invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

100: Lighting device
11: Main plate
12: Semiconductor (LED) element
13: Protection filter
14: Awning
15: Support bracket
20: Cooling unit
21a:
21b: Skirt
21: Plate
23: cooling pin
24: Cone air guide
30: Protective cover
31: Main cover
32: Auxiliary cover
35: air inlet chamber
40: blowing fan

Claims (10)

A main plate having a first surface and a second surface opposite to the first surface;
A plurality of light emitting elements arranged on a first surface of the main plate;
An awning formed on an upper surface of the main plate;
A rotatable support bracket for installation on other structures;
A cooling plate having a first surface fixed to a second surface of the main plate and a second surface opposite to the first surface, the air inlet being provided at a portion corresponding to the central portion, and a fixing pillar being formed at both sides of the rear surface or the rear surface;
The cooling plate being vertically protruded from the plane of the second surface of the cooling plate and being arranged radially outwardly and radially curved about a central portion of the cooling plate, A plurality of cooling fins formed in a widened curved cross-sectional shape to guide the air flow path formed along the surface of the cooling plate into a spiral or spiral path;
Wherein the cooling plate has a plurality of cooling fins and a plurality of cooling fins, the plurality of cooling fins having a common plane on which an upper end portion of the plurality of cooling fins is located is brought into contact with an upper end of the cooling fin to form an air flow path in a direction parallel to the plane of the cooling plate A guide plate having an air inlet hole corresponding thereto;
A cone-shaped air guide formed to guide the vertically incident air around the bottom of the air inlet facing the air inlet;
A blowing fan for supplying air from the outside to the air inflow portion through an air inflow hole of the guide plate and supplying cooling air to one end of the cooling fin; And
A main cover having an air outlet at an edge thereof facing the cooling plate, and an auxiliary cover covering a rear portion of the main cover, wherein a slit-shaped air inlet is provided radially between the main cover and the auxiliary cover, And the discharge port includes a protective cover provided radially as a whole except for a portion where the fixed post piece is formed,
Wherein the main cover is integrally coupled to the support bracket so as to be rotatable by the fixing post of the cooling plate and the fastening means provided on the outside. delete delete delete The method according to claim 1,
And the guide plate is formed on the protective cover. delete delete delete delete delete

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